Chemical Substitution Effect of Thiophenoxyl Radicals Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 415
http://dx.doi.org/10.5012/bkcs.2013.34.2.415
Chemical Substitution Effect on Energetic and Structural Differences between
Ground and First Electronically Excited States of Thiophenoxyl Radicals
Jun-Ho Yoon, Jeong Sik Lim,a Kyung Chul Woo, Myung Soo Kim,† and Sang Kyu Kim*
Department of Chemistry, KAIST, Daejeon 305-701, Korea. *E-mail: [email protected]†School of Chemistry, Seoul National University, Seoul 151-742, Korea
Received October 28, 2012, Accepted November 12, 2012
Effect of chemical substitution at the para-position of the thiophenoxyl radical has been theoretically
investigated in terms of energetics, structures, charge densities and orbital shapes for the ground and first
electronically excited states. It is found that the adiabatic energy gap increases when CH3 or F is substituted at
the para-position. This change is attributed to the stabilization of the ground state of thiophenoxyl radical
through the electron-donating effect of F or CH3 group as the charge or spin of the singly-occupied molecular
orbital is delocalized over the entire molecule especially in the ground state whereas in the excited state it is
rather localized on sulfur and little affected by chemical substitutions. Quantitative comparison of predictions
based on four different quantum-mechanical calculation methods is presented.
Key Words : Substitution effect, Thiophenoxyl, Spin distribution, Chemical energetics
Introduction
Recent studies on the πσ* mediated photodissociationdynamics have revealed many interesting facets of multi-dimensional conical intersection seam through which non-adiabatic transitions become facilitated effectively. The firstelectronically excited state corresponding to the ππ* tran-sition is bound in nature whereas an upper-lying πσ* state isrepulsive along a specific chemical bond. In this way,potential energy surfaces of the excited states are forced tobe crossed at particular nuclear configurations, generating amulti-dimensional conical intersection seam along the photo-dissociation reaction pathway. This type of excited statedynamics is frequently met in a number of photochemicalpathways as π conjugated systems coupled with a hetero-atom such as oxygen, nitrogen, or sulfur are quite ubiquitousin many fields of chemistry and biology. These includephenol,1-3 anisole,4,5 aniline,6,7 pyrrole,8-10 thiophenol,2,11-13
and thioanisole,14 giving rise to H or CH3 fragment upon UVexcitation as the X-H(CH3) bond dissociation takes place (X= O, N, or S) along the repulsive πσ* state. Bond dis-sociation dynamics is very sensitive to the electronic/nuclearcoupling mechanism at nuclear configurations constructingthe reaction coordinate, and thus chemical substitutions onthe aromatic ring moiety could induce significant effects onthe whole chemical reaction dynamics as the π conjugationof the aromatic ring moiety which may be sensitive to thechemical substitution should modify potential energy surfacesin terms of energetics and morphology.
In this respect, we studied here chemical substitutioneffect on the thiophenoxyl radical in the ground and firstelectronically excited states. From the recent photodissoci-
ation dynamics studies on thiophenols2,11-13 and thioani-soles,14 it has been found that the thiophenoxyl radical isproduced either in the ground state, C6H5S· ( ), or in thefirst electronically excited state, C6H5S· ( ). Relative yieldsof two competing reaction channels are governed by thenonadiabatic transition probability of the reactive flux at theconical intersection seam. Experimentally, using velocity-map ion imaging or Rydberg-tag technique, one could pre-cisely estimate the branching ratio between these two channelsas the small but distinct energy gap between C6H5S· ( ) andC6H5S· ( ) allows separation of two adiabatic channels inthe total translational distribution of products. The adiabaticenergy gap between C6H5S· ( ) and C6H5S· ( ) was pre-cisely measured to be 0.3719 eV by the Neumark group,15
and this is quite consistent with theoretical predictionscalculated by Lee et al. some time ago.16 The - energygap of the thiophenoxyl radical is very small for the energydifference between two electronic states, which could beattributed to the poor conjugation of nonbonding orbital ofsulfur (3p) with the π orbital (2p) of the benzene moiety.17
Therefore, it is a natural question how the energy gapbetween p-Y-C6H4S· ( ) and p-Y-C6H4S· ( ) will bechanged as the electron donating or withdrawing Y group issubstituted instead of H. Though the substitution effect onthe S-H bond dissociation energy of thiophenols had beenpreviously studied,18-23 those studies were naturally focusedonly on the ground state of the thiophenoxyl radical.
Computational Detail
State-averaged complete active space self-consistent field(SA-CASSCF) and density functional theory (DFT) methodswere employed for the calculation of the electronicallyexcited states of thiophenoxyl radicals. In the SA-CASSCF,active space of 9 electrons distributed over 8 molecular
XA
XA
X A
A X
X A
aCurrent address: Center for Gas Analysis, Korea Research Institute ofStandards and Science (KRISS), Daejeon 305-340, Korea
416 Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 Jun-Ho Yoon et al.
orbitals was considered whereas aug-cc-pVTZ24,25 basis setwas used in order to depict partial Rydberg character of theexcited state. Complete active space second-order perturba-tion (CASPT2) and cluster-corrected (Davidson correction)multireference configuration interaction (MRCI+Q) are alsoemployed for further consideration of dynamic electroncorrelation. Geometries of the ground and first excited stateswere fully optimized by CASPT2 or DFT for the calcu-lations of vertical and adiabatic energy gap between twostates and harmonic vibrational frequencies. SA-CASSCF,CASPT2, and MRCI+Q calculations were carried out usingMOLPRO26 whereas Gaussian 09 program27 was used forDFT calculations and natural bonding orbital (NBO) ana-lyses.28
Results and Discussion
Optimized geometry parameters of thiophenoxyl radicalsin the ground and excited states, calculated by CASPT2 andDFT, are given in Table 1 for C6H5S·, p-F-C6H4S·, and p-CH3-C6H4S· with corresponding atomic labels depicted inFigure 1. One of notable geometrical differences betweenground and excited states of thiophenoxyl radicals is the C-Sbond length change. For instance, the C-S bond length of
C6H5S· is lengthened by 0.041 (0.040) Å in the excited statecompared to that in the ground state according to CASPT2(DFT). Lengthening of C-S bond upon (symmetry-forbi-dden) electronic excitation also applies to the case of p-F-C6H4S· and p-CH3-C6H4S·. Interestingly, the C-S bond lengthremains more or less same as F and CH3 groups are para-substituted in the excited state whereas it is slightly shorten-ed in the ground state, Table 1. This already suggests that π-conjugation of thiophenoxyl radicals in the excited state issomewhat different from that in the ground state. Other geo-metrical parameters are little sensitive to the para-sub-stitution of F or CH3, indicating that electron donating effectof F or CH3 group is not significant enough for inducingstructural changes in both excited and ground states ofthiophenoxyl radicals.
The most accurate value for the adiabatic - energygap of C6H5S· is calculated to be 0.367 eV by CASPT2/aug-cc-pVTZ, which is in good agreement with the most recentexperimental value of 0.3719 eV.15 It should be noted thatour theoretical result is slightly different from a previouslyreported value of 0.376 eV by Cheng et al.,16 and this seemsto result from the use of two-state averaged reference func-tion for the consideration of electron correlation in this workwhereas the single state wave function was used in Ref. 16.
A X
Table 1. Calculated geometry parameters of and state of substituted thiophenoxyl radicals obtained at the level of CASPT2 and DFT.Units are angstroms for the bond length and degrees for the angle. See Figure 1 for the representative atom labels
C6H5S· p-F-C6H4S· p-CH3-C6H4S·a
CASPT2 DFTb CASPT2 DFT CASPT2 DFT
2B1/A"
r1C7S
r1C2C
r2C3C
r3C4C
r2C8H
r3C9H
r4C12(H/F/C)
α6C1C2C
α1C2C3C
α2C3C4C
α1C2C8H
α4C3C9H
1.711
1.418
1.388
1.400
1.081
1.081
1.081
118.7
120.4
120.1
118.4
119.9
1.723
1.414
1.382
1.395
1.080
1.081
1.081
118.4
120.6
120.1
118.6
120.0
1.709
1.419
1.387
1.393
1.081
1.080
1.342
118.5
120.9
118.4
118.5
119.6
1.721
1.415
1.381
1.389
1.080
1.080
1.343
118.2
121.1
118.5
118.6
119.7
1.708
1.419(1.418)
1.385(1.388)
1.406(1.403)
1.081
1.083
1.500
118.1
120.6
121.1
118.4
119.2
1.720
1.415(1.413)
1.379(1.382)
1.403(1.400)
1.080
1.083(1.082)
1.502
117.8
120.8
121.2
118.5(118.6)
119.3
2B2/A'
r1C7S
r1C2C
r2C3C
r3C4C
r2C8H
r3C9H
r4C12(H/F/C)
α6C1C2C
α1C2C3C
α2C3C4C
α1C2C8H
α4C3C9H
1.752
1.402
1.394
1.396
1.082
1.081
1.081
119.9
119.7
120.6
120.1
120.1
1.763
1.398
1.389
1.390
1.081
1.082
1.081
119.6
119.8
120.7
120.2
120.1
1.753
1.402
1.394
1.387
1.081
1.080
1.348
119.7
120.2
118.9
120.2
119.8
1.765
1.398
1.389
1.382
1.081
1.081
1.352
119.5
120.3
119.0
120.3
119.9
1.752
1.403(1.400)
1.393(1.395)
1.400(1.397)
1.082
1.083
1.502
119.4
119.8
121.6
120.1
119.5(119.4)
1.765
1.398(1.395)
1.387(1.390)
1.396(1.393)
1.081
1.083
1.506
119.1
120.0(119.9)
121.7(121.8)
120.2(120.3)
119.6(119.5)
ap-CH3-C6H4S· of molecular symmetry Cs can have two different values for each pair of bond lengths and angles in contrast with C2v symmetry. Thesevalues are shown in parentheses. bThe DFT calculation has been carried out using B3LYP functional
X A
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A
Chemical Substitution Effect of Thiophenoxyl Radicals Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 417
Vertical energy gap is calculated to be 0.400 eV by CASPT2for C6H5S· which is 0.033 eV higher than the adiabaticenergy gap, suggesting that the structural change of thearomatic ring moiety upon electronic excitation should bequite significant. Generally, it is found that SA-CASSCF(0.285 eV) and MRCI+Q (0.325 eV) predictions under-estimate the adiabatic - energy gap whereas it is over-estimated by a DFT value of 0.384 eV. Upon para-sub-stitution of F and CH3 on the aromatic ring moiety, theadiabatic - energy gap is calculated to be increased by0.040 (323 cm−1) or 0.039 (315 cm−1) eV, respectively, accord-ing to the CASPT2/aug-cc-pVTZ calculation. Similarly,calculations with other methods also predict the larger -energy gap for p-F-C6H4S· and p-CH3-C6H4S· compared tothat of C6H5S·, Table 2. SA-CASSCF (or MRCI+Q) gives202 (282) or 177 (242) cm−1 for F and CH3 substitution,respectively, for the increase of the - energy gap, whichis smaller than that predicted by CASPT2. On the otherhand, DFT gives 492 or 444 cm−1 upon F or CH3 para-sub-stitution, respectively. The increase in the adiabatic -energy gap upon para-substitution is predicted to be slightlylarger for F compared to CH3 from all of four calculationmethods. This trend is somewhat less straightforward to
understand as the CH3 group is believed to be the strongerelectron donor compared to F (vide infra). Though CASPT2seems to be most consistent with the experiment for C6H5S·,it will be quite intriguing to investigate which method wouldbe more appropriate for explaining the effect of para-substitution as different quantum mechanical methods havetheir own advantages in different circumstances.
Qualitative description for the origin of the structural andenergetic changes of thiophenoxyl radicals upon chemicalsubstitution can be given based on the charge and spin den-
A X
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A X
A X
A X
Figure 1. Molecular structures of the (a) C6H5S·, (b) p-F-C6H4S·and (c) p-CH3-C6H4S·.
Table 2. Theoretically obtained vertical excitation energies andadiabatic excitation energies for the 2B1/A" and 2B2/A'electronic states of the substituted thiophenoxyl radicals calculatedusing the SA-CASSCF, CASPT2, MRCI+Q, and DFT methods.Units are eV
2B2/A' ← 2B1/A" Excitation energies
vertical adiabatic
C6H5S·
SA-CASSCF
CASPT2
MRCI+Q
DFT
0.354
0.400
0.376
0.416
0.285
0.367
0.325
0.384
Exp[15] 0.3719
p-F-C6H4S·
SA-CASSCF
CASPT2
MRCI+Q
DFT
0.383
0.448
0.419
0.487
0.310
0.407
0.360
0.445
p-CH3-C6H4S·
SA-CASSCF
CASPT2
MRCI+Q
DFT
0.388
0.446
0.415
0.477
0.307
0.406
0.355
0.439
X A
A X
Table 3. Mulliken and NBO charge densities for the and state of substituted thiophenoxyl radicals obtained from DFT calculation atthe aug-cc-pVTZ basis level. See Figure 1 for the representative atom labels
C6H5S· p-F-C6H4S· p-CH3-C6H4S·
Mulliken NBO Mulliken NBO Mulliken NBO
2B1/A"
1C
2C
3C
4C
7S
8H
9H
12H/12F/12C
0.512
-0.696
-0.340
-0.272
-0.365
0.475
0.421
0.404
-0.242
-0.164
-0.209
-0.154
0.079
0.218
0.210
0.207
0.436
-0.505
-0.615
0.716
-0.371
0.552
0.403
-0.454
-0.255
-0.147
-0.269
0.439
0.074
0.222
0.227
-0.323
0.506
-0.545(-0.707)
-0.749(-0.801)
1.340
-0.385
0.485(0.461)
0.218(0.377)
-0.769
-0.245
-0.155(-0.157)
-0.215(-0.213)
0.034
0.062
0.217
0.206
-0.606 2B2/A'
1C
2C
3C
4C
7S
8H
9H
12H/12F/12C
0.666
-0.818
-0.272
-0.359
-0.289
0.480
0.398
0.405
-0.227
-0.229
-0.180
-0.220
0.229
0.209
0.206
0.206
0.576
-0.629
-0.549
0.662
-0.285
0.545
0.391
-0.470
-0.243
-0.208
-0.244
0.384
0.230
0.212
0.223
-0.337
0.704
-0.667(-0.805)
-0.717(-0.786)
1.310
-0.303
0.470(0.451)
0.207(0.357)
-0.776
-0.234
-0.220(-0.218)
-0.185(-0.183)
-0.035
0.222
0.208(0.207)
0.202
-0.596
X A
X
A
418 Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 Jun-Ho Yoon et al.
sity distributions calculated by Mulliken29 or NBO analysis,Tables 3 and 4. Absolute values are less reliable as thosepopulation analyses are not theoretically strict, and onlyqualitative trends should be taken to be meaningful. Accord-ing to the Mulliken analysis by DFT/aug-cc-pVTZ, thepartial charge on the sulfur atom decreases as F or CH3 isbeing substituted on the para-position for the ground state.Even though NBO analysis gives the positive value for thecharge density on sulfur, it also shows the decrease for theground state thiophenoxyl radicals as electron donatinggroups are being substituted on the ring. This behavior isquite perceivable considering the Hammett-Brown polarsubstituent constant (σp
+)30 of F and CH3 as the linear depen-dence is observed when the change of S charge density isplotted versus σp
+, Figure 2. For excited states of thiophen-oxyl radicals, however, the charge density on sulfur byMulliken or NBO is decreased by the CH3 substitution whileit is slightly increased by the F substitution, suggesting that
Table 4. Mulliken and NBO spin densities for the and state of substituted thiophenoxyl radicals obtained from DFT calculation at theaug-cc-pVTZ basis level. See Figure 1 for the representative atom labels
C6H5S· p-F-C6H4S· p-CH3-C6H4S·
Mulliken NBO Mulliken NBO Mulliken NBO
2B1/A"
1C
2C
3C
4C
7S
8H
9H
12H/12F/12C
-0.071
0.127
-0.070
0.176
0.798
-0.008
0.002
-0.006
-0.072
0.145
-0.069
0.179
0.752
-0.005
0.002
-0.005
-0.060
0.125
-0.070
0.158
0.778
-0.005
0.002
0.021
-0.065
0.138
-0.062
0.157
0.741
-0.005
0.002
0.021
-0.067
0.134(0.114)
-0.072(-0.071)
0.188
0.779
-0.008(-0.007)
0.005(0.004)
-0.017
-0.065
0.146(0.134)
-0.066
0.177
0.733
-0.005(-0.004)
0.002
-0.008 2B2/A'
1C
2C
3C
4C
7S
8H
9H
12H/12F/12C
-0.074
0.013
0.022
-0.003
1.069
-0.030
-0.001
-0.001
-0.022
0.013
0.003
-0.003
0.993
-0.001
0.001
0.000
-0.081
0.018
0.026
0.001
1.069
-0.037
-0.001
0.001
-0.022
0.013
0.003
-0.003
0.993
-0.001
0.001
0.000
-0.058
0.007(0.011)
0.027(0.029)
-0.005
1.061
-0.034(-0.037)
0.001(-0.001)
0.000
-0.022
0.013(0.014)
0.003
-0.003
0.993
-0.001
0.001
0.000
X A
X
A
Figure 2. (Left) Plot of the calculated change in NBO chargedensity of the sulfur atom as a function of the σp
+ constant of thepara-substituent for the ( ) and ( ) state. The morenegative value of σp
+, the stronger electron donating ability. TheMulliken charge is not shown for its similarity. (Right) Plot of theexcitation energy change by para-substitution calculated usingCASPT2 as a function of the change in spin density of the sulfuratom. The spin densities from the both NBO ( ) and Mulliken ( )population analysis give good correlations.
X A
Figure 3. DFT SOMOs generated by B3LYP and SA-CASSCFSOMOs associated with electronically ground states (upper panel)and excited states (lower panel) for (a) C6H5S·, (b) p-F-C6H4S· and(c) p-CH3-C6H4S·. The orbitals were visualized using Gauss Viewand MOLDEN respectively with an isovalue of 0.020.
Chemical Substitution Effect of Thiophenoxyl Radicals Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 419
the electron-donating effect of F or CH3 is not manifested forthe excited state. The more consistent behavior could befound by the spin density calculations, Table 4. The spindensity is calculated to be localized on sulfur for bothground and excited states of all thiophenoxyl radicalsstudied in this work from both Mulliken and NBO analyses.Especially, for excited states, the spin density is found to belocalized solely on sulfur, and it is little changed by the F orCH3 para-substitution.
On the other hand, the S spin density of 0.798 (0.752) ofC6H5S· decreases to 0.778 (0.741) and 0.779 (0.733), respec-tively, for p-F-C6H4S· and p-CH3-C6H4S· in the ground state
according to Mulliken (NBO) analysis. The decrease of theS spin density with F or CH3 substitution for the ground stateof thiophenoxyl radical is quite similar, and this indeedcorrelates well with the behavior of the adiabatic -energy gap with chemical substitution, Figure 2. That is, thespin density on sulfur becomes delocalized with F or CH3
para-substitution by the same extent for the ground state ofthiophenoxyl radicals, whereas it is little affected by thechemical substitution in the excited state. Therefore, thestabilization of the ground state through spin delocalizationcontributes to the increase of the adiabatic - energy gapwith F or CH3 substitution. The importance of spin delocali-zation in energetics of substituted phenoxyl radicals hadbeen reported by Fehir et al.,31 and our findings here arequite consistent. Orbital shapes of singly-occupied mole-cular orbitals (SOMO) for ground and excited states ofC6H5S·, p-F-C6H4S·, and p-CH3-C6H4S· radicals calculatedby DFT or SA-CASSCF strongly suggest that SOMO islocalized on sulfur in the excited state and both charge andspin densities are little affected by the F or CH3 para-sub-stitution, Figure 3. Harmonic vibrational frequencies ofground and excited states of C6H5S·, p-F-C6H4S·, and p-CH3-C6H4S· radicals calculated by DFT-B3LYP/aug-cc-pVTZ are given in Table 5. A scale factor of 0.9687 wasmultiplied for all presented numbers, based on the com-parison of the experimental and theoretical values for groundstate of C6H5S·.32 The zero-point energy differences between
and states are calculated to be very small, giving 18,34, and 30 cm-1 for C6H5S·, p-F-C6H4S·, and p-CH3-C6H4S·radicals, respectively.
Conclusion
We investigated here the chemical substitution effect onthe energetics and structure of first electronically excited andground states of thiophenoxyl radical. Para-substitution ofF and CH3 groups certainly increases the adiabatic -energy gap by 323 or 315 cm−1, respectively, according toCASPT2 though other theoretical methods such as SA-CASSCF, MRCI+Q, or DFT give slightly different numbers.Our Mulliken or NBO analysis gives a hint that the spindensity on sulfur, which becomes somewhat delocalized bythe chemical substitution in the ground state, could bemainly responsible for the increase of the - energy gapas the spin density in the excited thiophenoxyl radical issolely localized on sulfur and little affected by para-sub-stitution whatsoever. Geometrical and vibrational changesupon F or CH3 para-substitution are less pronounced.Theoretical results presented here should be essential for thephotodissociation studies of thiophenols or thioanisoleswhich are excellent chemical systems for interrogatingconical intersection dynamics. Furthermore, because state of thiophenoxyl radical is quite unique in terms ofenergetics and spin property, it would be very exciting toinvestigate chemical reactivity of p-Y-C6H4S· ( ) to becompared with that of p-Y-C6H4S· ( ) of different Ygroups. Photodissociation of thiophenols could certainly be
A X
A X
A X
A X
A X
A
AX
Table 5. Harmonic vibrational frequencies for the and stateof C6H5S·, p-F-C6H4S· and p-CH3-C6H4S· obtained using DFT. Allunits are cm−1
mode symmetryC6H5S· p-F-C6H4S·a p-CH3-C6H4S·a
ν1
ν2
ν3
ν4
ν5
ν6
ν7
ν8
ν9
ν10
ν11
A1 (A') 3103
3091
3072
1546
1439
1162
1048
1009
977
709
414
3096
3082
3066
1569
1458
1169
1064
1015
981
685
397
3109
1221
3095
1552
1450
1139
1046
994
810
640
372
3102
1211
3081
1577
1470
1144
1062
999
806
611
361
3098
1194
3068
1559
1452
1169
1046
1001
789
636
377
3083
1193
3058
1585
1472
1174
1061
1004
784
610
364
ν12
ν13
ν14
A2 (A") 971
826
373
956
822
408
960
798
385
941
798
420
971
819
378
953
816
411
ν15
ν16
ν17
ν18
ν19
ν20
B1 (A") 984
922
750
666
450
156
974
885
724
683
463
174
953
833
708
501
299
108
927
812
690
492
319
120
958
810
702
483
271
104
931
789
698
480
288
113
ν21
ν22
ν23
ν24
ν25
ν26
ν27
ν28
ν29
ν30
B2 (A') 3100
3081
1529
1418
1302
1261
1142
1062
603
288
3086
3072
1553
1417
1313
1252
1145
1063
610
237
3107
3096
1528
1387
1272
1257
411
1077
617
258
3101
3083
1563
1375
1285
1247
403
1084
621
215
3096
3064
1506
1390
1287
1258
362
1098
623
244
3082
3061
1539
1377
1299
1247
347
1104
629
207
ν31
ν32
ν33
ν34
ν35
ν36
ν37
ν38
ν39
A'
A"
A'
A'
A"
A'
A"
A'
A"
3009
2970
2928
1440
1437
1370
1026
972
47
3003
2972
2929
1447
1441
1372
1034
973
28
aThe numbering of p-F-C6H4S· and p-CH3-C6H4S· vibrational modes mapthrough from the corresponding normal modes of the C6H5S· radical.
X A
X A X A X A
420 Bull. Korean Chem. Soc. 2013, Vol. 34, No. 2 Jun-Ho Yoon et al.
used for the controlled generation of states of thiophen-oxyl radicals for further exciting stereo-specific chemicalreaction studies.
Acknowledgments. We appreciate financial support fromGrants of National Research Foundation (2012-0005607,SRC 2012-0000779).
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